[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5713/ajas.2009.70091

Effect of Inorganic and Organic Trace Mineral Supplementation on the Performance, Carcass Characteristics, and Fecal Mineral Excretion of Phase-fed, Grow-finish Swine

Burkett, J.L. (Department of Animal Science, Iowa State University)
Stalder, K.J. (Department of Animal Science, Iowa State University)
Powers, W.J. (Department of Animal Science, Iowa State University)
Bregendahl, K. (Department of Animal Science, Iowa State University)
Pierce, J.L. (Alltech Inc.)
Baas, T.J. (Department of Animal Science, Iowa State University)
Bailey, T. (Department of Statistics, Iowa State University)
Shafer, B.L. (Alltech Inc.)

Publication Information

Asian-Australasian Journal of Animal Sciences / v.22, no.9, 2009 , pp. 1279-1287 More about this Journal

Abstract

Concentrated livestock production has led to soil nutrient accumulation concerns. To reduce the environmental impact, it is necessary to understand current recommended livestock feeding practices. Two experiments were conducted to compare the effects of trace mineral supplementation on performance, carcass composition, and fecal mineral excretion of phase-fed, grow-finish pigs. Crossbred pigs (Experiment 1 (Exp. 1), (n = 528); Experiment 2 (Exp. 2), (n = 560)) were housed in totally-slatted, confinement barns, blocked by weight, penned by sex, and randomly assigned to pens at approximately 18 kg BW. Treatments were allocated in a randomized complete block design (12 replicate pens per treatment) with 9 to 12 pigs per pen throughout the grow-finish period. In Exp. 1, the control diet (Io100) contained Cu as $CuSO_{4}$ , Fe as $FeSO_{4}$ , and Zn (of which 25% was ZnO and 75% was $ZnO_{4}$ ) at concentrations of 63 and 378 mg/kg, respectively. Treatment 2 (O100) contained supplemental Cu, Fe, and Zn from organic sources (Bioplex, Alltech Inc., Nicholasville, KY) at concentrations of 19, 131, and 91 mg/kg, respectively, which are the commercially recommended dietary inclusion levels for these organic trace minerals. Organic Cu, Fe, and Zn concentrations from O100 were reduced by 25% and 50% to form treatments 3 (O75) and 4 (O50-1), respectively. In Exp. 2, treatment 5 (Io25) contained 25% of the Cu, Fe, and Zn (inorganic sources) concentrations found in Io100. Treatment 6 (O50-2) was identical to the O50-1 diet from Exp. 1. Treatment 7 (O25) contained the experimental microminerals reduced by 75% from concentrations found in O100. Treatment 8 (O0) contained no trace mineral supplementation and served as a negative control for Exp. 2. In Exp. 1, tenth-rib backfat, loin muscle area and ADG did not differ (p>0.05) between treatments. Pigs fed the control diet (Io100) consumed less feed (p<0.01) compared to pigs fed diets containing organic trace minerals, thus, G:F was greater (p = 0.03). In Exp. 2, there were no differences among treatment means for loin muscle area, but pigs fed the reduced organic trace mineral diets consumed less (p<0.05) feed and tended (p = 0.10) to have less tenth-rib backfat compared to pigs fed the reduced inorganic trace mineral diet. Considering that performance and feed intake of pigs was not affected by lower dietary trace mineral inclusion, mineral excretion could be reduced during the grow-finish phase by reducing dietary trace mineral concentration.

Keywords

Fecal Excretion; Performance; Pigs; Trace Minerals;

Citations & Related Records

Times Cited By KSCI : 1 (Citation Analysis)
Times Cited By Web Of Science : 0 (Related Records In Web of Science)
Times Cited By SCOPUS : 0

Reference
Cited By KSCI

1	Hill, G. M., G. L. Cromwell, T. D. Crenshaw, C. R. Dove, R. C. Ewan, D. A. Knabe, A. J. Lewis, G. W. Libal, D. C. Mahan, G. C. Shurson, L. L. Southern and T. L. Veum. 2000. Growth promotion effects and plasma changes from feeding high dietary concentrations of zinc and copper to weanling pigs (regional study). J. Anim. Sci. 78:1010-1016 PUBMED
2	Luecke, R. W., J. A. Hoefer, W. S. Brammell and F. Thorp, Jr. 1956. Mineral interrelationships in parakeratosis of swine. J. Anim. Sci. 15:347-351
3	van Heugten, E., P. R. O' Quinn, D. W. Funderburke, W. L. Flowers and J. W. Spears. 2004. Growth performance, carcass characteristics, plasma minerals, and fecal mineral excretion in grower-finisher swine fed diets with levels of trace minerals lower than common industry levels. J. Swine Health Prod. 12:237-241
4	Besser, J. M. 2001. Early life-stage toxicity of copper to endangered and surrogate fish species. US. 126 Environmental Protection Agency, Washington, DC
5	Hill, G. M. and E. R. Miller. 1983. Effect of dietary zinc levels on the frowth and development of the gilt. J. Anim Sci. 57:106-113 DOI PUBMED ScienceOn
6	Lewis, P. K., Jr., W. G. Hoekstra, R. H. Grummer and P. H. Phillips. 1956. The effect of certain nutritional factors including calcium, phosphorus and zinc on parakeratosis in swine. J. Anim. Sci. 15:741-751
7	Wedekind, K. J., A. E. Hortin and D. H. Baker. 1992. Methodology for assessing zinc bioavailability: efficacy estimates for zinc-methionine, zinc sulfate, and zinc oxide. J. Anim. Sci. 70:178-187 PUBMED
8	Carlson, M. S., G. M. Hill and J. E. Link. 1999. Early- and traditionally weaned nursery pigs benefit from phase-feeding pharmacological concentrations of zinc oxide: effect on metallothionein and mineral concentrations. J. Anim Sci. 77:1199-1207 PUBMED
9	Creech, B. L., J. W. Spears, W. L. Flowers, G. M. Hill, K. E. Lloyd, T. A. Armstrong and T. E. Engle. 2004. Effect of dietary trace mineral concentration and source (inorganic vs. chelated) on performance, mineral status, and fecal mineral excretion in pigs from weaning through finishing. J. Anim Sci. 82:2140-2147 PUBMED
10	Acda, S. P., J. W. Joo, W. T. Kim, Y. H. Shim, S. H. Lee, B. J. Chae. 2002. Influence of a single dose of Fe Dextran administration with organic trace mineral supplementation on the performance of piglets. Asian-Aust. J. Anim. Sci. 15:1469-1474
11	NRC. 1998. Nutrition requirements of swine. 10th. rev. ed. Natl. Acad. Press, Washington, DC
12	Bates, R. O. and L. L. Christian. 1994. The national swine improvement federation guidelines for ultrasonic certification programs. Fact Sheet NSIF-FS16, Cooperative Extension Service, Purdue Univ., West Lafayette
13	National Pork Board. 2003. Swine care handbook. National Pork Board, Des Moines, IA, USA
14	Spears, J. W. 1996. Optimizing mineral levels and sources for farm animals. CRC Press, Inc., Boca Raton, FL
15	Hahn, J. D. and D. H. Baker. 1993. Growth and plasma zinc responses of young pigs fed pharmacologic levels of zinc. J. Anim. Sci. 71:3020-3024 PUBMED
16	Hill, D. A., E. R. Peo, Jr., A. J. Lewis and J. D. Crenshaw. 1986. Zinc-amino acid complexes for swine. J. Anim Sci. 63:121-130 PUBMED

2	Bing Liu. (2016) Biological Trace Element Research Effects of Replacing of Inorganic Trace Minerals by Organically Bound Trace Minerals on Growth Performance, Tissue Mineral Status, and Fecal Mineral Excretion in Commercial Grower-Finisher Pigs / 173 (2) , 316
1559-0720	(2017) Biological Trace Element Research Growth Performance, Mineral Digestibility, and Blood Characteristics of Ostriches Receiving Drinking Water Supplemented with Varying Levels of Chelated Trace Mineral Complex / (1559-0720)
4	(2009) Archives of animal nutrition Effects of the different levels of dietary trace elements from organic or inorganic sources on growth performance, carcass traits, meat quality, and faecal mineral excretion of broilers / 73 (4) , 324
1	(2009) Journal of applied animal nutrition Effect of total replacement of inorganic with organic sources of key trace minerals on performance and health of high producing dairy cows / 9 (1) , 23
1	(2021) Tropical animal health and production Effect of replacing inorganic trace minerals at lower organic levels on growth performance, blood parameters, antioxidant status, immune indexes, and fecal mineral excretion in weaned piglets / 53 (1) , 121